对飞机分布式推进声干扰研究的贡献

Q2 Engineering

CEAS Aeronautical Journal Pub Date : 2023-09-20 DOI:10.1007/s13272-023-00679-6

Sébastien Guérin, Damiano Tormen

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引用次数: 0

摘要

为了更好地理解分布式推进发动机产生的声干扰，本文采用了一种将RANS仿真结果用于气动预测和分析模型相结合的方法来计算声学。在这项研究中考虑了一个没有机翼的多螺旋桨配置。螺旋桨的几何形状和工作条件符合支线运输机的要求。在论文的第一部分，比较了两种不同的、独立的预测方法得到的结果。一种方法已经建立，并作为第二种低阶方法的验证，这种方法更适合于设计噪声应用，因为它需要更少的细节作为输入，并且计算速度快了几个数量级。本文第二部分利用这两种方法在单螺旋桨和分布式螺旋桨配置下的良好一致性来研究声干扰的作用。考虑声干扰会极大地影响音调发射的方向性。与考虑螺旋桨不相关的结果相比，在辐射节点处远场声压级可以显着降低或放大到8个螺旋桨计算的9db的理论极限。指向性模式取决于螺旋桨的相对初始角位置。当这些位置根据均匀概率密度分布模型随机变化时，平均结果(期望)与认为螺旋桨不相关时相同。最后，结果表明，由于所得压力幅值的概率分布呈正偏态，声级低于平均值的概率大于50%。尽管没有考虑螺旋桨-螺旋桨和螺旋桨-机翼的相互作用，但由于这些相互作用是转子锁相的，因此研究结果的本质有望在更复杂的构型中保持有效。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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A contribution to the investigation of acoustic interferences in aircraft distributed propulsion

Abstract The objective of this work is to better understand the acoustic interferences created by distributed propulsion engines based on an approach that combines RANS simulation results for the aerodynamic prediction and analytical models to calculate acoustics. A multi-propeller configuration without wing is considered for this investigation. The propeller geometry and the operating conditions are realistic for a regional transport airplane. In the first part of the paper, the results obtained by two different and independent prediction methods are compared. One method is well-established and serves as validation for the second, low-order method, which is better suited for design-to-noise applications since it requires less details as input and is computationally faster by several orders of magnitude. The good agreement between both methods, obtained for a single propeller as well as for the distributed propeller configuration, is exploited in the second part of the paper to investigate the role of acoustic interferences. Taking acoustic interferences into account drastically affects the directivity of the tonal emission. Compared to the results obtained by considering the propellers as if they were uncorrelated, the far-field sound pressure levels can be significantly lower at the radiation nodes or amplified up to the theoretical limit of 9 dB calculated for eight propellers. The directivity patterns depend on the relative initial angular positions of the propellers. When these positions are randomly varied according to the uniform probability density distribution model, the mean result (expectation) is the same as if the propellers were considered as uncorrelated. Finally, the results show that the probability that the acoustic level is lower than the mean value is higher than 50% because of the positive skewness of the probability distribution of the resulting pressure amplitude. Even though the propeller–propeller and propeller–wing interactions were not considered, the essence of the findings is expected to remain valid for more complex configurations because those interactions are rotor phase-locked.

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来源期刊

CEAS Aeronautical Journal Engineering-Aerospace Engineering

CiteScore

3.40

自引率

0.00%

发文量

期刊介绍： The CEAS Aeronautical Journal has been created under the umbrella of CEAS to provide an appropriate platform for excellent scientific publications submitted by scientists and engineers. The German Aerospace Center (DLR) and the European Space Agency (ESA) support the Journal.The Journal is devoted to publishing results and findings in all areas of aeronautics-related science and technology as well as reports on new developments in design and manufacturing of aircraft, rotorcraft, and unmanned aerial vehicles. Of interest are also (invited) in-depth reviews of the status of development in specific areas of relevance to aeronautics, and descriptions of the potential way forward. Typical disciplines of interest include flight physics and aerodynamics, aeroelasticity and structural mechanics, aeroacoustics, structures and materials, flight mechanics and flight control, systems, flight guidance, air traffic management, communication, navigation and surveillance, aircraft and aircraft design, rotorcraft and propulsion.The Journal publishes peer-reviewed original articles, (invited) reviews and short communications.